US20190264678A1 - Control system and control method - Google Patents
Control system and control method Download PDFInfo
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- US20190264678A1 US20190264678A1 US16/348,140 US201716348140A US2019264678A1 US 20190264678 A1 US20190264678 A1 US 20190264678A1 US 201716348140 A US201716348140 A US 201716348140A US 2019264678 A1 US2019264678 A1 US 2019264678A1
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B49/00—Control, e.g. of pump delivery, or pump pressure of, or safety measures for, machines, pumps, or pumping installations, not otherwise provided for, or of interest apart from, groups F04B1/00 - F04B47/00
- F04B49/06—Control using electricity
- F04B49/065—Control using electricity and making use of computers
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B17/00—Pumps characterised by combination with, or adaptation to, specific driving engines or motors
- F04B17/03—Pumps characterised by combination with, or adaptation to, specific driving engines or motors driven by electric motors
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B49/00—Control, e.g. of pump delivery, or pump pressure of, or safety measures for, machines, pumps, or pumping installations, not otherwise provided for, or of interest apart from, groups F04B1/00 - F04B47/00
- F04B49/06—Control using electricity
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R19/00—Arrangements for measuring currents or voltages or for indicating presence or sign thereof
- G01R19/165—Indicating that current or voltage is either above or below a predetermined value or within or outside a predetermined range of values
- G01R19/16533—Indicating that current or voltage is either above or below a predetermined value or within or outside a predetermined range of values characterised by the application
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B19/00—Programme-control systems
- G05B19/02—Programme-control systems electric
- G05B19/18—Numerical control [NC], i.e. automatically operating machines, in particular machine tools, e.g. in a manufacturing environment, so as to execute positioning, movement or co-ordinated operations by means of programme data in numerical form
- G05B19/414—Structure of the control system, e.g. common controller or multiprocessor systems, interface to servo, programmable interface controller
- G05B19/4142—Structure of the control system, e.g. common controller or multiprocessor systems, interface to servo, programmable interface controller characterised by the use of a microprocessor
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B2203/00—Motor parameters
- F04B2203/02—Motor parameters of rotating electric motors
- F04B2203/0202—Voltage
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B2203/00—Motor parameters
- F04B2203/02—Motor parameters of rotating electric motors
- F04B2203/0205—Temperature
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B2203/00—Motor parameters
- F04B2203/02—Motor parameters of rotating electric motors
- F04B2203/0209—Rotational speed
Definitions
- the present disclosure relates to a control system, and in particular to a control system and a control method for controlling communications.
- a control system controls the electric pump to operate.
- the electric pump includes a motor and a rotor.
- the motor drives the rotor to rotate, and a control system of the electric pump controls the motor to rotate.
- the control system of the electric pump includes a master controller, a microprocessor and a communication system.
- the master controller sends a control signal to the microprocessor via the communication system.
- the microprocessor analyzes the control signal, so as to control the motor to rotate.
- the microprocessor feeds back the operation state of the electric pump to the master controller via the communication system.
- the master controller is a controller of a vehicle.
- the microprocessor is integrated in a printed circuit board of the electric pump. Control signals and feedback signals are transmitted between the master controller and the microprocessor via the communication system.
- the communication system processes communication protocols between the master controller and the microprocessor. In order to prevent mutual interference between signals, the control signal and the feedback signal are transmitted through separated signal lines, which results in a complex connection of the control system.
- the present disclosure aims to provide a control system and a control method to achieve a simple system connection and an accurate control.
- the control system includes a master controller, a microprocessor and a signal line.
- the master controller is configured to send a control signal to the microprocessor via the signal line.
- the microprocessor is configured to send the control signal to the execution device to drive the execution device to operate, acquire, at a time interval, a feedback signal representing an operation state of the execution device, and send the feedback signal to the signal line.
- the master controller is further configured to acquire the feedback signal from the signal line; determine, from the feedback signal, the operation state of the execution device; and regulate the control signal based on the operation state.
- a control method performed by a control system is further provided according to an embodiment of the present disclosure.
- the control system includes a master controller and a microprocessor.
- the control method includes: sending, by the master controller, a control signal of PWM waveform with a duty cycle, where the duty cycle corresponds to a target rotating speed of the execution device; receiving the control signal and analyzing the control signal by the microprocessor, and generating a drive signal to drive the execution device to operate.
- the control method further includes an event processing step, where an event list is prestored.
- the event list includes multiple pieces of event information representing event states.
- the control method further includes: acquiring, by the microprocessor, at a time interval, a current operation state of the execution device; determining, by the microprocessor, whether the current operation state of the execution device is consistent with the event state corresponding to a piece of event information in the prestored event list; and enabling or disabling, by the microprocessor, the piece of event information in the prestored event list and sending a feedback signal to the master controller.
- the master controller is connected to the microprocessor via a single signal line.
- the microprocessor includes a communication module and a control module.
- the master controller sends the control signal to the communication module via the signal line.
- the control module acquires feedback information, and sends the feedback information to the signal line via the communication module.
- the master controller acquires the feedback information from the signal line. In this way, interface terminals of the system are reduced, leading to a simple structure. With the feedback system, the control is performed more timely and more accurately.
- FIG. 1 is a schematic block diagram showing a control system:
- FIG. 2 is a schematic block diagram showing a master controller and a microcontroller shown in FIG. 1 ;
- FIG. 3 is a schematic block diagram showing communication between the master controller and the microprocessor shown in FIG. 1 via a communication circuit;
- FIG. 4 is a schematic diagram showing a first connection structure of the communication circuit shown in FIG. 3 according to an embodiment
- FIG. 5 is a schematic diagram showing a second connection structure of the communication circuit shown in FIG. 3 to an embodiment
- FIG. 6 is a flowchart showing a control flow performed by a control system
- FIG. 7 is a flowchart showing a sending mode shown in FIG. 6 ;
- FIG. 8 is a flowchart showing a feedback mode shown in FIG. 6 .
- the electric pump in an embodiment is applied to a vehicle thermal management system.
- the electric pump includes a motor.
- the control system controls operation of the motor so as to control operation of the electric pump.
- the control system includes a master controller ECU, a microprocessor MCU and a signal line BUS.
- the master controller ECU sends a control signal to the microprocessor MCU via the signal line BUS.
- the microprocessor MCU sends the control signal to the electric pump.
- the microprocessor MCU acquires, at a time interval, a feedback signal representing an operation state of the electric pump and sends the feedback signal to the signal line BUS.
- the master controller ECU acquires the feedback signal from the signal line BUS.
- the master controller ECU determines, from the feedback signal, the operation state of the electric pump, and regulates the control signal based on the operation state.
- the master controller ECU includes a first communication module 10 and a first control module 20 .
- the microprocessor MCU includes a second communication module 30 and a second control module 40 .
- the master controller ECU sends the control signal to the second communication module 30 via the signal line BUS, the second communication module 30 converts the control signal into a first control signal.
- the second control module 40 acquires the first control signal, and converts the first control signal into a second control signal.
- the second control module 40 sends the second control signal to the electric pump.
- the second control module 40 acquires, at a time interval, a first feedback signal representing the operation state of the electric pump, and converts the first feedback signal into a second feedback signal.
- the second feedback signal is sent to the second communication module 30 and converted into a third feedback signal.
- the third feedback signal is sent to the signal line BUS.
- the master controller ECU acquires the third feedback signal.
- the master controller ECU determines, from the third feedback signal, the operation state of the electric pump, and regulates the control signal based on the operation state. In this way, the signal is sent and fed back between the microprocessor MCU and the master controller ECU via a single signal line BUS. Therefore, interface terminals of the control system are reduced, leading to a simple structure. With the feedback system, the master controller can control the execution device more timely and more accurately.
- the execution device is the electric pump.
- the execution device may be other electronic components including motors, such as an electronic expansion valve or an electronic water valve.
- the motor in this embodiment includes a stator assembly and a rotor assembly.
- the feedback signal can be obtained by detecting the stator assembly and/or the rotor assembly or obtained from the stator assembly and/or the rotor assembly.
- the third feedback signal is in a form of a combination of a duration of the current control signal and a duration of a low level signal.
- the first control module 20 includes a first storage module 3 .
- the first storage module 3 prestores multiple combinations of the duration of the control signal representing the operation state of the electric pump and the duration of the low level signal, which form a combination list.
- the master controller ECU compares the third feedback signal acquired by the master controller ECU with the combinations in the combination list prestored in the first storage module 3 , to determine the current operation state of the electric pump. In this way of forming the third feedback signal as the combination of the duration of the control signal and the duration of the low level signal, it is advantageous to improve generality and portability of the control system and the microprocessor.
- the operation state of the electric pump includes a normal state and an event state.
- the normal state indicates that the electric pump operates following the control signal sent by the master controller ECU.
- the event state indicates that the electric pump operates not following the control signal sent by the master controller ECU.
- the second control module 40 acquires the first feedback signal.
- the second control module 40 includes a second storage module 4 .
- the second storage module 4 prestores operation states.
- the second control module acquires the first feedback signal representing the current operation state. In a case that the current operation state is same as one of the prestored operation states, the current operation state of the execution device is determined as the prestored operation state and the second feedback signal including the event information is generated.
- the first feedback signal includes an operating current of the motor.
- the microprocessor MCU acquires the operating current and determines, based on the operating current, the operation state of the execution device. In this case, the operation state of the detected execution device includes an overcurrent state, a stalled state, a dry-running state and other event states.
- the first feedback signal further includes three-phase voltages of the motor.
- the microprocessor MCU acquires the three-phase voltages of the motor, and determines whether the execution device is in an overvoltage state, an under-voltage state, or other event states.
- the first feedback signal further includes a voltage of an NTC (Negative Temperature Coefficient) thermistor.
- the microprocessor MCU acquires the voltage of the NTC thermistor, and determines whether the execution device is in an over-temperature state or other event states.
- the second control module 40 determines the current operation state of the electric pump from the acquired feedback signal, generates the second feedback signal.
- the second feedback signal is sent to the second communication module to generate the third feedback signal.
- the master controller ECU acquires the third feedback signal and generates the control signal corresponding to the current operation state of the execution device in response to the third feedback signal, so as to control the operation state of the execution device.
- the third feedback signal is in a form of the combination of the duration of the current control signal from the signal line BUS and the duration of the low level signal, to represent the operation state of the execution device.
- the operation state of the execution device is the normal state.
- the third feedback signal is a combination of the duration of 1.5 s of the current control signal and the duration of 1 s of the pull-down level signal, the operation state of the execution device is the stalled state.
- the operation state of the execution device is the dry-running state.
- the operation state of the execution device is the over-temperature state.
- the operation state of the execution device is the overcurrent state.
- the operation state of the execution device is the under-voltage state or the over-voltage state.
- the master controller ECU includes an output unit 1 and an input unit 2 .
- the master controller ECU outputs the control signal via the output unit 1 , to the signal line BUS.
- the master controller ECU acquires the third feedback signal from the signal line BUS via the input unit 2 .
- the output unit 1 includes an output interface 11 and an output circuit.
- the input unit 2 includes an input interface 22 and an input circuit.
- the output circuit includes a first transistor Q 1 .
- a base of the first transistor Q 1 serves as an input electrode for the control signal.
- An emitter of the first transistor Q 1 is grounded via a first resistor R 1 .
- a collector of the first transistor Q 1 is connected to the output interface 11 .
- the output circuit with this configuration is advantageous to improve the drive capability of the control signal.
- the input circuit includes a second transistor Q 2 .
- a base of the second transistor Q 2 is connected to the input interface 22 .
- the master controller ECU acquires the third feedback signal via the input interface 22 .
- An emitter of the second transistor Q 2 is grounded.
- a collector of the second transistor Q 2 is connected to a power supply via a second resistor R 2 .
- the configuration of second resistor R 2 is advantageous to pull up a voltage of the collector of the second transistor Q 2 .
- the control system includes a sending system and a feedback system.
- the control signal controls the operation of the electric pump via the sending system.
- the feedback signal is fed back to the master controller via the feedback system.
- the second communication module 30 includes a sending submodule 31 and a feedback submodule 32 .
- the sending submodule 31 includes a signal identification module 5 and a signal storage module 9 .
- the feedback submodule 32 includes an event adding module 6 and an event storage module 7 .
- the sending submodule is a part of the sending system.
- the feedback submodule is a part of the feedback system.
- the signal identification module 5 is configured to: receive the control signal from the master controller ECU; and determine whether the received control signal is a signal of a PWM (Pulse Width Modulation) waveform. In a case that the control signal is not a signal of a PWM waveform, the control signal is an abnormal signal. In this case, a value is assigned for the abnormal signal and the feedback system does not operate.
- the microprocessor MCU generates a first control signal to drive the motor to operate at a maximum rotating speed. In a case that the control signal is a signal of a PWM waveform, the signal identification module 5 analyzes the control signal to obtain a duty cycle and frequency of the control signal.
- the duty cycle is a percent of the duration of the high level of the control signal in a period of the control signal.
- the frequency is the number of periodic changes of the control signal per unit of time. It is determined whether the duty cycle and the frequency of the control signal are both correct. In a case that both of the duty cycle and the frequency of the PWM signal is correct, the control signal is stored in the signal storage module 9 , so as to be acquired by the second control module 40 .
- the duty cycle being incorrect includes the duty cycle being a 0 duty cycle, a 100% duty cycle and an error duty cycle.
- the 0 duty cycle indicates that the control signal is always in a low level state.
- the 100% duty cycle indicates that the control signal is always in a high level state.
- the error duty cycle includes a case that in 6 successive control signals inputted to the second communication module, a difference between a maximum of the duty cycle and a minimum of the duty cycle is greater than 1%, and a duration of this situation is greater than or equal to 2 s, and a case that in 6 successive control signals inputted to the second communication module, a difference between the maximum of the duty cycle and a minimum of the duty cycle is greater than 1%, and a duration of this situation is greater than is and equal to or less than 2 s.
- the control signal is an abnormal signal.
- a value is assigned for the abnormal signal, and the feedback system does not operate.
- the second communication module generates the first control signal to drive the motor to operate at the maximum rotating speed.
- the first control signal is stored in the signal storage module 9 , so as to be acquired by the second control module.
- the control signal is the abnormal signal.
- a value is assigned for the abnormal signal, and the feedback system does not operate.
- the second communication module 30 generates the first control signal to drive the motor to operate at the rotating speed corresponding to the previous control signal.
- the first control signal is stored in the signal storage module 9 , so as to be acquired by the second control module 40 .
- the frequency being incorrect includes a case that in 6 successive control signals inputted to the second communication module, a ratio of the difference between a maximum of the frequency and a minimum of the frequency to the maximum of the frequency is greater than 1%, and a duration of this situation is greater than or equal to 2 s.
- the control signal is an abnormal signal.
- a value is assigned for the abnormal signal and the feedback system does not operate.
- the second communication module generates the first control signal to drive the motor to operate at the maximum rotating speed.
- the first control signal is stored in the signal storage module 9 , so as to be acquired by the second control module.
- the feedback submodule 32 includes the event adding module 6 and the event storage module 7 .
- the event adding module 6 is configured to add the event information.
- the added event information forms an event list and is stored in the event storage module 7 , such that the event storage module 7 prestores the event list.
- the feedback submodule 32 further includes an event operating module 8 .
- the event operating module 8 is configured to receive the second feedback signal and acquire current event information included in the second feedback signal. In a case that the current event information is same as one of the event information in the event list, the event information is determined to be reported or not reported, and a corresponding third feedback signal is generated.
- the event information includes an event number, a priority, an enable bit, a minimum times of reporting, a duration of the control signal, and a duration of a pull-down voltage.
- the event number indicates a number assigned to the operation state of the execution device represented by the second feedback signal. For example, the normal state is numbered by 1, the stalled state is numbered by 2, the dry-running state is numbered by 3, the over-voltage state is numbered by 4, and the under-voltage state is numbered by 5. In a case that multiple second feedback signals occur, a second feedback signal having a highest priority is firstly used to generate the third feedback signal.
- the minimum times of reporting indicates, for each generated second feedback signal, the number of times of the third feedback signal being generated and sent to the signal line.
- the duration of the control signal indicates, in the feedback system, a length of time for which the control signal lasts in the signal line.
- the duration of the pull-down voltage indicates a length of time for which the pull-down voltage lasts in the signal line.
- the control system further includes a communication circuit.
- the communication circuit may be arranged between the master controller ECU and the microprocessor MCU or integrated in the second communication module.
- the communication circuit includes a sending unit and a feedback unit.
- the sending unit is a part of the sending system.
- the feedback unit is a part of the feedback system.
- the communication circuit includes a wide range voltage inputting module, a first connection terminal 101 , a second connection terminal 102 and a third connection terminal 103 .
- the first connection terminal 101 is connected to the master controller ECU.
- the second connection terminal 102 and the third connection terminal 103 are connected to the microprocessor MCU.
- the wide range voltage inputting module is arranged near the first connection terminal 101 .
- the control signal is inputted to the communication circuit via the wide range voltage inputting module, so that the wide range voltage inputting module always outputs a voltage of 0V when being inputted with any voltages ranging from 0V to 2.5V, which is advantageous to avoid influence on the PWM signal due to voltage fluctuation.
- FIG. 4 is a schematic diagram showing a first connection structure of the communication circuit.
- the sending unit includes a third resistor R 3 , a fourth resistor R 4 , a fifth resistor R 5 and a third transistor Q 3 .
- the wide range voltage inputting module includes the third resistor R 3 and the fourth resistor R 4 which are connected in series with each other. The wide range voltage input function is achieved by setting resistances of the third resistor R 3 and the fourth resistor R 4 .
- the signal line BUS is connected to the first connection terminal 101 .
- the control signal is divided via the third resistor R 3 and the fourth resistor R 4 , and then is connected to a base of the third transistor Q 3 via the fifth resistor R 5 to control the third transistor Q 3 to be switched on or switched off, so as to control the second connection terminal 102 to send or not send the first control signal to a PMW pin of the microprocessor MCU.
- the sending unit further includes a sixth resistor R 6 .
- the sixth resistor R 6 serves as a pull-up resistor for the collector of the third transistor Q 3 .
- a power supply VCC supplies power to the third transistor Q 3 via the sixth resistor R 6 .
- the third resistor R 3 and the fourth resistor R 4 forms the wide range voltage inputting module to operate as follows.
- a voltage of the low level ranges from 0 to 2V.
- the control signal is transmitted to the base of the third transistor Q 3 after being divided by the third resistor R 3 and the fourth resistor R 4 .
- the third transistor Q 3 is controlled to be in an off state. In this case, the collector of the third transistor Q 3 outputs a high level, achieving the wide range voltage input function for the low level of the control signal.
- the sending unit operates as follows. In a case that the control signal is in a high level, a voltage of the high level ranges from 7V to 20V.
- the control signal is transmitted to the base of the third transistor Q 3 after being divided by the third resistor R 3 and the fourth resistor R 4 .
- the third transistor Q 3 In a case that the divided voltage to the base of the third transistor Q 3 is greater than the turn-on voltage of the third transistor Q 3 , the third transistor Q 3 is in an on state. In this case, the collector of the third transistor Q 3 outputs a low level, that is, the outputted first control signal is 0.
- the third transistor Q 3 In a case that the voltage of the base of the third transistor Q 3 is less than the turn-on voltage of the third transistor Q 3 , the third transistor Q 3 is in the off state, and the collector of the third transistor Q 3 outputs a high level, that is, the outputted first control signal is in a high level.
- the communication circuit further includes a seventh resistor R 7 and a diode D 1 .
- the seventh resistor R 7 severs as a pull-up resistor for the output interface of the master controller ECU.
- the diode D 1 is configured to prevent the feedback signal from being inputted to the power supply to affect the level of signals on the bus.
- the microprocessor MCU includes a PWM interface and a second interface I/O.
- the second interface I/O is connected to the third connection terminal 103 of the communication circuit and sends the second feedback signal to the third connection terminal 103 .
- the feedback unit includes an eighth resistor R 8 , a ninth resistor R 9 , a tenth resistor R 10 and a fourth transistor Q 4 .
- the eighth resistor R 8 is a current limiting resistor.
- the ninth resistor R 9 severs as a pull-down resistor for a base of the fourth transistor Q 4 .
- the tenth resistor R 01 severs as a pull-up resistor for a collector of the fourth transistor Q 4 .
- the power supply VCC supplies power to the fourth transistor Q 4 via the tenth resistor R 10 .
- the feedback system operates as follows. In a case that the second feedback signal is in a high level, the fourth transistor Q 4 is in an on state, the signal outputted to the signal line BUS is in a low level. In a case that the second feedback signal is in a low level, the fourth transistor Q 4 is in an off state, and the signal outputted to the signal line BUS is in a high level.
- FIG. 5 is a schematic diagram showing a second connection structure of the communication circuit. Compared with the first connection structure of the communication circuit, the feedback unit in the second connection structure is same as that in the first embodiment.
- the sending unit includes a comparator 10 , an eleventh resistor R 11 , a twelfth resistor R 12 and a thirteenth resistor R 13 .
- the comparator 10 includes a positive terminal + and a negative terminal ⁇ .
- the twelfth resistor R 12 and the thirteenth resistor R 13 are voltage division resistors and generate an inputted reference voltage Vi.
- the twelfth resistor R 12 is connected to the positive terminal +. That is, the inputted reference voltage Vi is connected to the positive terminal +.
- the control signal is connected to the negative terminal ⁇ of the comparator via the eleventh resistor R 11 .
- the eleventh resistor R 11 is a current limiting resistor. In a case that that the inputted control signal is greater than the inputted reference voltage Vi, the comparator outputs a low level. In a case that that the inputted control signal is less than the inputted reference voltage Vi, the comparator outputs a high level.
- the inputted reference voltage Vi By configuring the inputted reference voltage Vi as 2.5V, a wide range voltage ranging from 0 to 2.5V is achieved.
- the control method includes a power-on step for the control system.
- the master controller sends a control signal of a PWM waveform with a duty cycle.
- the duty cycle represents a target rotating speed of the execution device.
- the microprocessor receives the control signal, analyzes the control signal, and generates the driving signal to drive the execution device to operate.
- the communication method further includes an event processing step.
- An event list is prestored for the event processing step.
- the event list includes multiple pieces of event information representing event states.
- the event information in the event list is determined to be reported or not reported via a preset program.
- the microprocessor acquires the current operation state of the execution device at a time interval. In a case that the current operation state is same as the event state corresponding to one of pieces of event information in the event list, the microprocessor determines to report or not report the piece of event information in the event list and feeds back to the master controller.
- the event information includes an event number, event feedback information and an enable bit. Each event number corresponds to an operation state of the execution device.
- the event feedback information includes a combination of a high voltage and a low voltage, which is generated corresponding to the current operation state of the execution device and fed back to the master controller. In a case that the enable bit is 1, the event information is reported. In a case that the enable bit is 0, the event information is not reported.
- the event information further includes an event priority and an event feedback times.
- the microprocessor acquires multiple current operation states of the execution device at a same time, a piece of event information with a higher priority is fed back to the master controller prior to a piece of event information with a lower priority.
- the event feedback times indicates a minimum number of times of feeding back the event information to the master controller.
- the control method further includes an initialization step for the control system.
- the initialization step includes a hardware initialization, a software initialization, and adding the event information to form the event list.
- the initialization step is performed after the power-on step.
- the adding the event information is performed after software initialization is performed.
- the control method further includes a state machine processing step.
- the state machine processing step is performed after the master controller sends the control signal.
- the state machine processing step includes: acquiring, at a time interval, the control signal; determining a state of the control signal; and activating an operation mode based on the state of the control signal.
- the operation mode includes a normal operation mode, an error shutdown mode and an error operation mode.
- the microprocessor In the normal operation mode, the microprocessor generates a drive signal to drive the execution device to operate at a target rotating speed.
- the microprocessor In the error operation mode, the microprocessor generates a drive signal to drive the execution device to operate at a maximum rotating speed.
- the microprocessor stops sending the drive signal to the execution device to cause the execution device to maintain the operation state.
- the state of the control signal includes the control signal having a correct duty cycle and a correct frequency, and the control signal having an incorrect duty cycle and/or an incorrect frequency.
- the state machine processing step is performed in the normal operation mode.
- the state machine processing step is performed in the error shutdown mode or the error operation mode.
- the incorrect duty cycle includes a 0 duty cycle and a 100% duty cycle, in which case the state machine processing step is performed in the error operation mode.
- the incorrect duty cycle further includes an error duty cycle.
- the error duty cycle includes a case that, in 6 successive control signals of the PWM waveform inputted to the microprocessor, a difference between a maximum of the duty cycle and a minimum of the duty cycle is greater than 1%, and a duration of this situation is equal to or greater than 2 s. In this case, the state machine processing step is performed in the error operation mode.
- the error duty cycle further includes a case that, in 6 successive control signals of the PWM waveform inputted to the microprocessor, a difference between a maximum of the duty cycle and a minimum of the duty cycle is greater than 1%, and a duration of this situation is greater than 1 s and less than 2 s.
- the state machine processing step is performed in the error shutdown mode.
- the frequency being incorrect includes a case that, in 6 successive control signals of the PWM waveform inputted to the microprocessor, a ratio of a difference between a maximum of the frequency and a minimum of the frequency to the maximum of the frequency is greater than 1%, and a duration of this situation is greater than a equal to 2 s.
- the state machine processing step is performed in the error operation mode.
- the frequency being incorrect further includes a case that, in 6 successive control signals of the PWM waveform through the microprocessor, a ratio of a difference between a maximum of the frequency and a minimum of the frequency to the maximum of the frequency is greater than 1%, and a duration of this situation is greater than 1 s and less than 2 s.
- the state machine processing step is performed in the error shutdown mode.
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Abstract
Description
- The present application claims the priority to Chinese Patent Application No. 201611009708.9, titled “COMMUNICATION CONTROL SYSTEM”, filed on Nov. 17, 2016 with the Chinese Patent Office, the priority to Chinese Patent Application No. 201611010424.1, titled “COMMUNICATION CONTROL SYSTEM”, filed on Nov. 17, 2016 with the Chinese Patent Office, and the priority to Chinese Patent Application No. 201611010014.7, titled “COMMUNICATION METHOD OF COMMUNICATION SYSTEM AND COMMUNICATION CONTROL SYSTEM”, filed on Nov. 17, 2016 with the Chinese Patent Office, which are incorporated herein by reference in their entireties.
- The present disclosure relates to a control system, and in particular to a control system and a control method for controlling communications.
- At present, electric pumps are generally applied in the refrigeration cycle of vehicles. A control system controls the electric pump to operate. The electric pump includes a motor and a rotor. The motor drives the rotor to rotate, and a control system of the electric pump controls the motor to rotate. The control system of the electric pump includes a master controller, a microprocessor and a communication system. The master controller sends a control signal to the microprocessor via the communication system. The microprocessor analyzes the control signal, so as to control the motor to rotate. The microprocessor feeds back the operation state of the electric pump to the master controller via the communication system.
- Generally, the master controller is a controller of a vehicle. The microprocessor is integrated in a printed circuit board of the electric pump. Control signals and feedback signals are transmitted between the master controller and the microprocessor via the communication system. The communication system processes communication protocols between the master controller and the microprocessor. In order to prevent mutual interference between signals, the control signal and the feedback signal are transmitted through separated signal lines, which results in a complex connection of the control system.
- Therefore, it is desired to improve the conventional technology, so as to solve the above technical problems.
- The present disclosure aims to provide a control system and a control method to achieve a simple system connection and an accurate control.
- The following technical solutions are provided according to an embodiment of the present disclosure. There is provided a control system for controlling operation of an execution device. The control system includes a master controller, a microprocessor and a signal line. The master controller is configured to send a control signal to the microprocessor via the signal line. The microprocessor is configured to send the control signal to the execution device to drive the execution device to operate, acquire, at a time interval, a feedback signal representing an operation state of the execution device, and send the feedback signal to the signal line. The master controller is further configured to acquire the feedback signal from the signal line; determine, from the feedback signal, the operation state of the execution device; and regulate the control signal based on the operation state.
- A control method performed by a control system is further provided according to an embodiment of the present disclosure. The control system includes a master controller and a microprocessor. The control method includes: sending, by the master controller, a control signal of PWM waveform with a duty cycle, where the duty cycle corresponds to a target rotating speed of the execution device; receiving the control signal and analyzing the control signal by the microprocessor, and generating a drive signal to drive the execution device to operate. The control method further includes an event processing step, where an event list is prestored. The event list includes multiple pieces of event information representing event states. The control method further includes: acquiring, by the microprocessor, at a time interval, a current operation state of the execution device; determining, by the microprocessor, whether the current operation state of the execution device is consistent with the event state corresponding to a piece of event information in the prestored event list; and enabling or disabling, by the microprocessor, the piece of event information in the prestored event list and sending a feedback signal to the master controller.
- In the present disclosure, the master controller is connected to the microprocessor via a single signal line. The microprocessor includes a communication module and a control module. The master controller sends the control signal to the communication module via the signal line. The control module acquires feedback information, and sends the feedback information to the signal line via the communication module. The master controller acquires the feedback information from the signal line. In this way, interface terminals of the system are reduced, leading to a simple structure. With the feedback system, the control is performed more timely and more accurately.
-
FIG. 1 is a schematic block diagram showing a control system: -
FIG. 2 is a schematic block diagram showing a master controller and a microcontroller shown inFIG. 1 ; -
FIG. 3 is a schematic block diagram showing communication between the master controller and the microprocessor shown inFIG. 1 via a communication circuit; -
FIG. 4 is a schematic diagram showing a first connection structure of the communication circuit shown inFIG. 3 according to an embodiment; -
FIG. 5 is a schematic diagram showing a second connection structure of the communication circuit shown inFIG. 3 to an embodiment; -
FIG. 6 is a flowchart showing a control flow performed by a control system; -
FIG. 7 is a flowchart showing a sending mode shown inFIG. 6 ; and -
FIG. 8 is a flowchart showing a feedback mode shown inFIG. 6 . - Hereinafter, the technical solution is further described in combination with the drawings and specific embodiments.
- The electric pump in an embodiment is applied to a vehicle thermal management system. The electric pump includes a motor. The control system controls operation of the motor so as to control operation of the electric pump. The control system includes a master controller ECU, a microprocessor MCU and a signal line BUS. The master controller ECU sends a control signal to the microprocessor MCU via the signal line BUS. The microprocessor MCU sends the control signal to the electric pump. The microprocessor MCU acquires, at a time interval, a feedback signal representing an operation state of the electric pump and sends the feedback signal to the signal line BUS. The master controller ECU acquires the feedback signal from the signal line BUS. The master controller ECU determines, from the feedback signal, the operation state of the electric pump, and regulates the control signal based on the operation state.
- Referring to
FIGS. 1 and 2 , the master controller ECU includes afirst communication module 10 and afirst control module 20. The microprocessor MCU includes asecond communication module 30 and asecond control module 40. The master controller ECU sends the control signal to thesecond communication module 30 via the signal line BUS, thesecond communication module 30 converts the control signal into a first control signal. Thesecond control module 40 acquires the first control signal, and converts the first control signal into a second control signal. Thesecond control module 40 sends the second control signal to the electric pump. Thesecond control module 40 acquires, at a time interval, a first feedback signal representing the operation state of the electric pump, and converts the first feedback signal into a second feedback signal. The second feedback signal is sent to thesecond communication module 30 and converted into a third feedback signal. The third feedback signal is sent to the signal line BUS. The master controller ECU acquires the third feedback signal. The master controller ECU determines, from the third feedback signal, the operation state of the electric pump, and regulates the control signal based on the operation state. In this way, the signal is sent and fed back between the microprocessor MCU and the master controller ECU via a single signal line BUS. Therefore, interface terminals of the control system are reduced, leading to a simple structure. With the feedback system, the master controller can control the execution device more timely and more accurately. - In this embodiment, the execution device is the electric pump. In fact, the execution device may be other electronic components including motors, such as an electronic expansion valve or an electronic water valve. The motor in this embodiment includes a stator assembly and a rotor assembly. The feedback signal can be obtained by detecting the stator assembly and/or the rotor assembly or obtained from the stator assembly and/or the rotor assembly.
- Reference is made to
FIG. 2 . In this embodiment, the third feedback signal is in a form of a combination of a duration of the current control signal and a duration of a low level signal. Thefirst control module 20 includes afirst storage module 3. Thefirst storage module 3 prestores multiple combinations of the duration of the control signal representing the operation state of the electric pump and the duration of the low level signal, which form a combination list. The master controller ECU compares the third feedback signal acquired by the master controller ECU with the combinations in the combination list prestored in thefirst storage module 3, to determine the current operation state of the electric pump. In this way of forming the third feedback signal as the combination of the duration of the control signal and the duration of the low level signal, it is advantageous to improve generality and portability of the control system and the microprocessor. - The operation state of the electric pump includes a normal state and an event state. The normal state indicates that the electric pump operates following the control signal sent by the master controller ECU. The event state indicates that the electric pump operates not following the control signal sent by the master controller ECU.
- In this embodiment, the
second control module 40 acquires the first feedback signal. Thesecond control module 40 includes asecond storage module 4. Thesecond storage module 4 prestores operation states. The second control module acquires the first feedback signal representing the current operation state. In a case that the current operation state is same as one of the prestored operation states, the current operation state of the execution device is determined as the prestored operation state and the second feedback signal including the event information is generated. The first feedback signal includes an operating current of the motor. The microprocessor MCU acquires the operating current and determines, based on the operating current, the operation state of the execution device. In this case, the operation state of the detected execution device includes an overcurrent state, a stalled state, a dry-running state and other event states. The first feedback signal further includes three-phase voltages of the motor. The microprocessor MCU acquires the three-phase voltages of the motor, and determines whether the execution device is in an overvoltage state, an under-voltage state, or other event states. The first feedback signal further includes a voltage of an NTC (Negative Temperature Coefficient) thermistor. The microprocessor MCU acquires the voltage of the NTC thermistor, and determines whether the execution device is in an over-temperature state or other event states. Thesecond control module 40 determines the current operation state of the electric pump from the acquired feedback signal, generates the second feedback signal. The second feedback signal is sent to the second communication module to generate the third feedback signal. The master controller ECU acquires the third feedback signal and generates the control signal corresponding to the current operation state of the execution device in response to the third feedback signal, so as to control the operation state of the execution device. - The third feedback signal is in a form of the combination of the duration of the current control signal from the signal line BUS and the duration of the low level signal, to represent the operation state of the execution device. For example, in a case that the third feedback signal is a combination of the duration of 4.5 s of the current control signal and the duration of 0.5 s of the pull-down level signal, the operation state of the execution device is the normal state. In a case that the third feedback signal is a combination of the duration of 1.5 s of the current control signal and the duration of 1 s of the pull-down level signal, the operation state of the execution device is the stalled state. In a case that the third feedback signal is a combination of the duration of is of the current control signal and the duration of 1 s of the pull-down level signal, the operation state of the execution device is the dry-running state. In a case that the third feedback signal is a combination of the duration of 2 s of the current control signal and the duration of 1 s of the pull-down level signal, the operation state of the execution device is the over-temperature state. In a case that the third feedback signal is a combination of the duration of 3 s of the current control signal and the duration of 1 s of the pull-down level signal, the operation state of the execution device is the overcurrent state. In a case that the third feedback signal is a combination of the duration of 2.5 s of the current control signal and the duration of 1 s of the pull-down level signal, the operation state of the execution device is the under-voltage state or the over-voltage state.
- Referring to
FIG. 3 , the master controller ECU includes an output unit 1 and aninput unit 2. The master controller ECU outputs the control signal via the output unit 1, to the signal line BUS. The master controller ECU acquires the third feedback signal from the signal line BUS via theinput unit 2. - The output unit 1 includes an
output interface 11 and an output circuit. Theinput unit 2 includes an input interface 22 and an input circuit. The output circuit includes a first transistor Q1. A base of the first transistor Q1 serves as an input electrode for the control signal. An emitter of the first transistor Q1 is grounded via a first resistor R1. A collector of the first transistor Q1 is connected to theoutput interface 11. The output circuit with this configuration is advantageous to improve the drive capability of the control signal. The input circuit includes a second transistor Q2. A base of the second transistor Q2 is connected to the input interface 22. The master controller ECU acquires the third feedback signal via the input interface 22. An emitter of the second transistor Q2 is grounded. A collector of the second transistor Q2 is connected to a power supply via a second resistor R2. The configuration of second resistor R2 is advantageous to pull up a voltage of the collector of the second transistor Q2. - The control system includes a sending system and a feedback system. The control signal controls the operation of the electric pump via the sending system. The feedback signal is fed back to the master controller via the feedback system.
- Referring to
FIG. 2 , thesecond communication module 30 includes a sendingsubmodule 31 and afeedback submodule 32. The sendingsubmodule 31 includes a signal identification module 5 and a signal storage module 9. Thefeedback submodule 32 includes an event adding module 6 and anevent storage module 7. The sending submodule is a part of the sending system. The feedback submodule is a part of the feedback system. - The signal identification module 5 is configured to: receive the control signal from the master controller ECU; and determine whether the received control signal is a signal of a PWM (Pulse Width Modulation) waveform. In a case that the control signal is not a signal of a PWM waveform, the control signal is an abnormal signal. In this case, a value is assigned for the abnormal signal and the feedback system does not operate. The microprocessor MCU generates a first control signal to drive the motor to operate at a maximum rotating speed. In a case that the control signal is a signal of a PWM waveform, the signal identification module 5 analyzes the control signal to obtain a duty cycle and frequency of the control signal. The duty cycle is a percent of the duration of the high level of the control signal in a period of the control signal. The frequency is the number of periodic changes of the control signal per unit of time. It is determined whether the duty cycle and the frequency of the control signal are both correct. In a case that both of the duty cycle and the frequency of the PWM signal is correct, the control signal is stored in the signal storage module 9, so as to be acquired by the
second control module 40. - The duty cycle being incorrect includes the duty cycle being a 0 duty cycle, a 100% duty cycle and an error duty cycle. The 0 duty cycle indicates that the control signal is always in a low level state. The 100% duty cycle indicates that the control signal is always in a high level state. The error duty cycle includes a case that in 6 successive control signals inputted to the second communication module, a difference between a maximum of the duty cycle and a minimum of the duty cycle is greater than 1%, and a duration of this situation is greater than or equal to 2 s, and a case that in 6 successive control signals inputted to the second communication module, a difference between the maximum of the duty cycle and a minimum of the duty cycle is greater than 1%, and a duration of this situation is greater than is and equal to or less than 2 s. In the case that the duty cycle is 0 or 100% or the case that the difference between the maximum of the duty cycle and the minimum of the duty cycle is greater than 1% and a duration of this situation is greater than or equal to 2 s, the control signal is an abnormal signal. In this case, a value is assigned for the abnormal signal, and the feedback system does not operate. The second communication module generates the first control signal to drive the motor to operate at the maximum rotating speed. The first control signal is stored in the signal storage module 9, so as to be acquired by the second control module. In the case that in 6 successive control signals inputted to the second communication module, a difference between the maximum of the duty cycle and the minimum of the duty cycle is greater than 1%, and a duration of this situation is greater than is and equal to or less than 2 s, the control signal is the abnormal signal. In this case, a value is assigned for the abnormal signal, and the feedback system does not operate. The
second communication module 30 generates the first control signal to drive the motor to operate at the rotating speed corresponding to the previous control signal. The first control signal is stored in the signal storage module 9, so as to be acquired by thesecond control module 40. - The frequency being incorrect includes a case that in 6 successive control signals inputted to the second communication module, a ratio of the difference between a maximum of the frequency and a minimum of the frequency to the maximum of the frequency is greater than 1%, and a duration of this situation is greater than or equal to 2 s. In a case that the frequency of the control signal is incorrect, the control signal is an abnormal signal. In this case, a value is assigned for the abnormal signal and the feedback system does not operate. The second communication module generates the first control signal to drive the motor to operate at the maximum rotating speed. The first control signal is stored in the signal storage module 9, so as to be acquired by the second control module.
- The
feedback submodule 32 includes the event adding module 6 and theevent storage module 7. The event adding module 6 is configured to add the event information. The added event information forms an event list and is stored in theevent storage module 7, such that theevent storage module 7 prestores the event list. The feedback submodule 32 further includes anevent operating module 8. Theevent operating module 8 is configured to receive the second feedback signal and acquire current event information included in the second feedback signal. In a case that the current event information is same as one of the event information in the event list, the event information is determined to be reported or not reported, and a corresponding third feedback signal is generated. - The event information includes an event number, a priority, an enable bit, a minimum times of reporting, a duration of the control signal, and a duration of a pull-down voltage. The event number indicates a number assigned to the operation state of the execution device represented by the second feedback signal. For example, the normal state is numbered by 1, the stalled state is numbered by 2, the dry-running state is numbered by 3, the over-voltage state is numbered by 4, and the under-voltage state is numbered by 5. In a case that multiple second feedback signals occur, a second feedback signal having a highest priority is firstly used to generate the third feedback signal. In a case that the enable bit of the event information is 1, the event information is reported, and in a case that the enable bit of the event information is 0, the event information is not reported. The minimum times of reporting indicates, for each generated second feedback signal, the number of times of the third feedback signal being generated and sent to the signal line. The duration of the control signal indicates, in the feedback system, a length of time for which the control signal lasts in the signal line. The duration of the pull-down voltage indicates a length of time for which the pull-down voltage lasts in the signal line.
- In this embodiment, the control system further includes a communication circuit. The communication circuit may be arranged between the master controller ECU and the microprocessor MCU or integrated in the second communication module. The communication circuit includes a sending unit and a feedback unit. The sending unit is a part of the sending system. The feedback unit is a part of the feedback system. Referring to
FIG. 4 , the communication circuit includes a wide range voltage inputting module, afirst connection terminal 101, asecond connection terminal 102 and athird connection terminal 103. Thefirst connection terminal 101 is connected to the master controller ECU. Thesecond connection terminal 102 and thethird connection terminal 103 are connected to the microprocessor MCU. The wide range voltage inputting module is arranged near thefirst connection terminal 101. - The control signal is inputted to the communication circuit via the wide range voltage inputting module, so that the wide range voltage inputting module always outputs a voltage of 0V when being inputted with any voltages ranging from 0V to 2.5V, which is advantageous to avoid influence on the PWM signal due to voltage fluctuation.
- Reference is made to
FIG. 4 , which is a schematic diagram showing a first connection structure of the communication circuit. The sending unit includes a third resistor R3, a fourth resistor R4, a fifth resistor R5 and a third transistor Q3. The wide range voltage inputting module includes the third resistor R3 and the fourth resistor R4 which are connected in series with each other. The wide range voltage input function is achieved by setting resistances of the third resistor R3 and the fourth resistor R4. The signal line BUS is connected to thefirst connection terminal 101. The control signal is divided via the third resistor R3 and the fourth resistor R4, and then is connected to a base of the third transistor Q3 via the fifth resistor R5 to control the third transistor Q3 to be switched on or switched off, so as to control thesecond connection terminal 102 to send or not send the first control signal to a PMW pin of the microprocessor MCU. The sending unit further includes a sixth resistor R6. The sixth resistor R6 serves as a pull-up resistor for the collector of the third transistor Q3. A power supply VCC supplies power to the third transistor Q3 via the sixth resistor R6. - The third resistor R3 and the fourth resistor R4 forms the wide range voltage inputting module to operate as follows. In a case that the control signal is in a low level, a voltage of the low level ranges from 0 to 2V. The control signal is transmitted to the base of the third transistor Q3 after being divided by the third resistor R3 and the fourth resistor R4. By configuring the divided voltage to the base of the third transistor Q3 to be less than a turn-on voltage of the third transistor Q3, the third transistor Q3 is controlled to be in an off state. In this case, the collector of the third transistor Q3 outputs a high level, achieving the wide range voltage input function for the low level of the control signal.
- The sending unit operates as follows. In a case that the control signal is in a high level, a voltage of the high level ranges from 7V to 20V. The control signal is transmitted to the base of the third transistor Q3 after being divided by the third resistor R3 and the fourth resistor R4. In a case that the divided voltage to the base of the third transistor Q3 is greater than the turn-on voltage of the third transistor Q3, the third transistor Q3 is in an on state. In this case, the collector of the third transistor Q3 outputs a low level, that is, the outputted first control signal is 0. In a case that the voltage of the base of the third transistor Q3 is less than the turn-on voltage of the third transistor Q3, the third transistor Q3 is in the off state, and the collector of the third transistor Q3 outputs a high level, that is, the outputted first control signal is in a high level.
- The communication circuit further includes a seventh resistor R7 and a diode D1. The seventh resistor R7 severs as a pull-up resistor for the output interface of the master controller ECU. The diode D1 is configured to prevent the feedback signal from being inputted to the power supply to affect the level of signals on the bus.
- The microprocessor MCU includes a PWM interface and a second interface I/O. The second interface I/O is connected to the
third connection terminal 103 of the communication circuit and sends the second feedback signal to thethird connection terminal 103. The feedback unit includes an eighth resistor R8, a ninth resistor R9, a tenth resistor R10 and a fourth transistor Q4. The eighth resistor R8 is a current limiting resistor. The ninth resistor R9 severs as a pull-down resistor for a base of the fourth transistor Q4. The tenth resistor R01 severs as a pull-up resistor for a collector of the fourth transistor Q4. The power supply VCC supplies power to the fourth transistor Q4 via the tenth resistor R10. - The feedback system operates as follows. In a case that the second feedback signal is in a high level, the fourth transistor Q4 is in an on state, the signal outputted to the signal line BUS is in a low level. In a case that the second feedback signal is in a low level, the fourth transistor Q4 is in an off state, and the signal outputted to the signal line BUS is in a high level.
-
FIG. 5 is a schematic diagram showing a second connection structure of the communication circuit. Compared with the first connection structure of the communication circuit, the feedback unit in the second connection structure is same as that in the first embodiment. The sending unit includes acomparator 10, an eleventh resistor R11, a twelfth resistor R12 and a thirteenth resistor R13. Thecomparator 10 includes a positive terminal + and a negative terminal −. The twelfth resistor R12 and the thirteenth resistor R13 are voltage division resistors and generate an inputted reference voltage Vi. The twelfth resistor R12 is connected to the positive terminal +. That is, the inputted reference voltage Vi is connected to the positive terminal +. The control signal is connected to the negative terminal − of the comparator via the eleventh resistor R11. The eleventh resistor R11 is a current limiting resistor. In a case that that the inputted control signal is greater than the inputted reference voltage Vi, the comparator outputs a low level. In a case that that the inputted control signal is less than the inputted reference voltage Vi, the comparator outputs a high level. By configuring the inputted reference voltage Vi as 2.5V, a wide range voltage ranging from 0 to 2.5V is achieved. - Referring to
FIGS. 6 to 8 , the control method includes a power-on step for the control system. The master controller sends a control signal of a PWM waveform with a duty cycle. The duty cycle represents a target rotating speed of the execution device. The microprocessor receives the control signal, analyzes the control signal, and generates the driving signal to drive the execution device to operate. The communication method further includes an event processing step. An event list is prestored for the event processing step. The event list includes multiple pieces of event information representing event states. The event information in the event list is determined to be reported or not reported via a preset program. The microprocessor acquires the current operation state of the execution device at a time interval. In a case that the current operation state is same as the event state corresponding to one of pieces of event information in the event list, the microprocessor determines to report or not report the piece of event information in the event list and feeds back to the master controller. - The event information includes an event number, event feedback information and an enable bit. Each event number corresponds to an operation state of the execution device. The event feedback information includes a combination of a high voltage and a low voltage, which is generated corresponding to the current operation state of the execution device and fed back to the master controller. In a case that the enable bit is 1, the event information is reported. In a case that the enable bit is 0, the event information is not reported.
- The event information further includes an event priority and an event feedback times. In a case that the microprocessor acquires multiple current operation states of the execution device at a same time, a piece of event information with a higher priority is fed back to the master controller prior to a piece of event information with a lower priority. The event feedback times indicates a minimum number of times of feeding back the event information to the master controller.
- The control method further includes an initialization step for the control system. The initialization step includes a hardware initialization, a software initialization, and adding the event information to form the event list. The initialization step is performed after the power-on step. The adding the event information is performed after software initialization is performed.
- The control method further includes a state machine processing step. The state machine processing step is performed after the master controller sends the control signal. The state machine processing step includes: acquiring, at a time interval, the control signal; determining a state of the control signal; and activating an operation mode based on the state of the control signal.
- The operation mode includes a normal operation mode, an error shutdown mode and an error operation mode. In the normal operation mode, the microprocessor generates a drive signal to drive the execution device to operate at a target rotating speed. In the error operation mode, the microprocessor generates a drive signal to drive the execution device to operate at a maximum rotating speed. In the error shutdown mode, the microprocessor stops sending the drive signal to the execution device to cause the execution device to maintain the operation state.
- The state of the control signal includes the control signal having a correct duty cycle and a correct frequency, and the control signal having an incorrect duty cycle and/or an incorrect frequency. In a case that the control signal has the correct duty cycle and the correct frequency, the state machine processing step is performed in the normal operation mode. In a case that the control signal has an incorrect duty cycle and/or an incorrect frequency, the state machine processing step is performed in the error shutdown mode or the error operation mode.
- The incorrect duty cycle includes a 0 duty cycle and a 100% duty cycle, in which case the state machine processing step is performed in the error operation mode. The incorrect duty cycle further includes an error duty cycle. The error duty cycle includes a case that, in 6 successive control signals of the PWM waveform inputted to the microprocessor, a difference between a maximum of the duty cycle and a minimum of the duty cycle is greater than 1%, and a duration of this situation is equal to or greater than 2 s. In this case, the state machine processing step is performed in the error operation mode. The error duty cycle further includes a case that, in 6 successive control signals of the PWM waveform inputted to the microprocessor, a difference between a maximum of the duty cycle and a minimum of the duty cycle is greater than 1%, and a duration of this situation is greater than 1 s and less than 2 s. In this case, the state machine processing step is performed in the error shutdown mode.
- The frequency being incorrect includes a case that, in 6 successive control signals of the PWM waveform inputted to the microprocessor, a ratio of a difference between a maximum of the frequency and a minimum of the frequency to the maximum of the frequency is greater than 1%, and a duration of this situation is greater than a equal to 2 s. In this case, the state machine processing step is performed in the error operation mode. The frequency being incorrect further includes a case that, in 6 successive control signals of the PWM waveform through the microprocessor, a ratio of a difference between a maximum of the frequency and a minimum of the frequency to the maximum of the frequency is greater than 1%, and a duration of this situation is greater than 1 s and less than 2 s. In this case, the state machine processing step is performed in the error shutdown mode.
- In this embodiment, functions of the master controller and the microprocessor are described in terms of modules and sub-modules.
- It should be noted that, the above embodiments are described only to illustrate but not intended to limit the technical solutions of the present disclosure. Although the technical solutions is described in detail with reference to the above embodiments, it should be understood by those skilled in the art that, various modifications and equivalents can be made to the technical solutions of the present disclosure without departing from the spirit and scope of the present disclosure, all of which should be contained within the scope of the claims of the present disclosure.
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CN201611009708.9A CN108073101A (en) | 2016-11-17 | 2016-11-17 | Communication control system |
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US10989187B2 (en) | 2021-04-27 |
EP3543533B1 (en) | 2021-03-31 |
WO2018090655A1 (en) | 2018-05-24 |
EP3543533A4 (en) | 2020-06-10 |
EP3543533A1 (en) | 2019-09-25 |
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